Bicycle Tire Pump

ABSTRACT

A pump that includes a body having a base and a top portion, wherein the base is configured to be anchored to the ground and the top portion is detachably connected to an upper plate in the body. The pump includes a handle assembly including a piston rod, handle bar, and cap that are detachably connected to each other by a fastener. The pump includes a tube positioned in the body. The tube slidably receives the piston rod and is connected to an air line. A hose is connected to the air line and extends from the body. The hose has a head configured to engage the nozzle of a tire. When the piston rod is moved downward within the tube, air is displaced from the tube and through the air line to the hose such that the head dispenses air.

RELATED APPLICATION

This application is a Continuation of, and claims priority to, U.S.patent application Ser. No. 16/404,403, filed on May 6, 2019, which is aContinuation of, and claims priority to, U.S. patent application Ser.No. 15/683,174, filed on Aug. 22, 2017, which is a Continuation of, andclaims priority to, U.S. patent application Ser. No. 14/485,311, filedon Sep. 12, 2014. U.S. patent application Ser. Nos. 14/485,311,15/683,174, and 16/404,403 are incorporated herein by reference and madea part hereof.

FIELD OF EMBODIMENTS OF THE INVENTION

Embodiments of the present invention generally relate to air pumps, and,more particularly, to air pumps for inflating bicycle tires.

BACKGROUND

In order for a bicycle to operate effectively, the air pressure in thetires of the bicycle should be maintained at a certain level. Over timeand over the course of use, bicycle tires leak air such that the airpressure in the tire decreases to an undesirable level. Therefore,bicycle users frequently need to refill the air in the tires of theirbicycles with an air pump. Such bike pumps include a piston rodpositioned in a tube body with a hose extending from the tube body. Ahandle is connected to the piston rod, and the hose has a head with anozzle that is configured to engage the air valve on a bike tire. Thebike user uses the handle to push the piston rod up and down in the tubebody, and, as the piston rod moves down, the piston pushes air from thetube body through the hose to the hose nozzle. The hose nozzle deliversthe air to the bike tire valve and inflates the bicycle tire with air.

While many bicyclists have their own portable bike pump which they keepat home or take with them on rides, “public” bicycle pumps exist thatare configured to be secured to the ground outdoors along bike paths orat parks, bike stations, or shops so that many different bicyclists canuse the pump.

Conventional bicycle pumps typically are lightweight and not made ofparticularly robust materials. The handle, piston rod, and tube body aretypically made of plastic, and the hose is typically made of rubber.Therefore, bicycle pumps, especially public pumps mounted outdoors, canwear out and break quickly from use and the elements. For example, thebike pump handle often breaks easily, and the hose can easily bedetached from the tube body or perforated. In addition, the hose istypically connected to the body of the pump by pressure fittings, so itis easy to detach from the pump. Moreover, because many of the parts ofa conventional bicycle pump are integrally formed together as a singleplastic piece, it is not easy to disassemble the bike pump or remove orreplace individual parts of the bike pump. For example, the piston rodand the handle may be integrally formed as a single plastic piece, butif only the handle becomes damaged, both the piston rod and the handleneed to be replaced. In fact, sometimes when an individual bike pumpcomponent does break or wear out, the whole pump must be replaced with anew pump because the component cannot be easily replaced.

SUMMARY OF EMBODIMENTS OF THE INVENTION

Certain embodiments of the present invention provide a pump forinflating tires with air. The pump includes a body having a base and atop portion. The base is configured to be anchored to the ground, andthe top portion is detachably connected to an upper plate in the body byfasteners. The pump includes a handle assembly that includes a pistonrod, handle bar, and cap that are detachably connected to each other bya fastener. The pump includes a tube positioned in the body and thatextends through the upper plate. The tube slidably receives the pistonrod and is connected to an air line. The pump includes a hose that isconnected to the air line and that extends from the body. The hose has ahead configured to engage the nozzle of a tire. When the piston rod ismoved downward within the tube, air is displaced from the tube andthrough the air line to the hose such that the head dispenses air.

The pump may further include a pressure gauge that is threadably mountedto the upper plate and that is positioned beneath the top portion. Thetop portion includes a transparent portion positioned over the gauge.The gauge has a face and a cover that define a chamber therebetween, andoil is located in the chamber.

The air line may include (a) a first air line that is connected at afirst end to a barbed fitting extending from the tube and that isconnected at a second end to a check valve, and (2) a second air linethat is connected at a first end to the check valve and that isconnected at a second end to an adaptor connected to the hose.

The pump hose may be threadably connected to an adapter that isconnected to the air line. The pump hose may be made in part of threadedmetal.

The piston rod may include a piston head on which is mounted twoflexible gaskets that each form a seal with an interior wall of thetube.

The pump handle assembly may include rubber grips that are slidablymounted to the handle bar.

The head of the hose may magnetically connect to the body.

Certain embodiments of the present invention provide a pump forinflating tires with air. The pump includes a body having a base and atop portion. The base has a hole configured to receive an anchor tosecure the base to the ground, and the top portion is detachablyconnected to an upper plate in the body by fasteners. The pump includesa handle assembly including a piston rod, handle bar, and handle capthat are detachably connected to each other by a fastener. The pumpincludes a tube positioned in the body and extending through the upperplate. The tube slidably receives the piston rod and is connected to anair line. A hose is connected to the air line and extends from the body.The hose has a head configured to engage the nozzle of a tire. The pumpincludes a pressure gauge that is detachably mounted to the upper plateand positioned beneath the top portion. The pressure gauge is connectedto the air line. When the piston rod is moved downward within the tube,air is displaced from the tube and through the air line to the hose suchthat the head dispenses air and the pressure gauge displays the pressureof the air in the air line.

Certain embodiments of the present invention provide a pump forinflating tires with air. The pump includes a body having an upperportion and a lower portion, wherein the lower portion includes a baseplate that is configured to be secured to the ground by an anchor. Thelower portion of the body has a greater outer diameter than the upperportion. The pump includes a handle assembly having a piston rod, handlebar, and handle cap that are detachably connected to each other by afastener. The pump includes a tube positioned in the upper portion ofthe body. The tube is slidably received in the piston rod. The pumpincludes an air line positioned in the lower portion of the body. Theair line is connected to the tube at one end and connected to an adapterat another end. The pump includes a hose that is connected to theadapter and that extends from the lower portion of the body. The hosehas a head configured to engage the nozzle of a tire. When the pistonrod is moved downward within the tube, air is displaced from the tubeand through the air line to the hose such that the head dispenses air.

BRIEF DESCRIPTION OF SEVERAL VIEWS OF THE DRAWINGS

FIG. 1 illustrates an isometric view of a pump according to anembodiment of the invention.

FIG. 2 illustrates a side view of the pump of FIG. 1.

FIG. 3 illustrates a sectional side view of the pump of FIG. 1 takenalong lines A-A.

FIG. 4 illustrates a partially exploded isometric view of the bicyclepump of FIG. 1.

FIG. 5 illustrates an exploded isometric view of parts of the pump ofFIG. 1.

FIGS. 6 illustrates an isometric view of a pump according to anembodiment of the present invention.

FIG. 7 illustrates a partially exploded isometric view of the pump ofFIG. 6.

FIG. 8 illustrates a sectional side view of a portion of the pump ofFIG. 6.

FIGS. 9 illustrates an isometric view of a pump according to anembodiment of the present invention.

FIG. 10 illustrates a partially exploded isometric view of the pump ofFIG. 9.

Before the embodiments of the invention are explained in detail, it isto be understood that the invention is not limited in its application tothe details of construction and the arrangement of the components setforth in the following description or illustrated in the drawings. Theinvention is capable of other embodiments and of being practiced orbeing carried out in various ways. Also, it is to be understood that thephraseology and terminology used herein are for the purpose ofdescription and should not be regarded as limiting. The use of“including” and “comprising” and variations thereof is meant toencompass the items listed thereafter and equivalents thereof as well asadditional items and equivalents thereof.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

FIGS. 1 and 2 illustrate a bicycle pump 10 according to an embodiment ofthe invention. The pump 10 includes a cylindrical body 14 connected to acircular base 18. The body 14 is open at the bottom end. The pump 10includes a transparent circular top portion 22 detachably mounted on thetop of the body 14 by connectors 16 such as tamper resistant bolts.Alternatively only a portion of the top portion 22 may be transparentand the remainder may be opaque. The base 18 includes holes 42 that areconfigured to receive anchors or other connectors to secure the pump 10to the ground or floor. Underneath the transparent top portion 22 is acircular plate 24 that includes a hole 46 in which is positioned an airpressure gauge 50. A gasket 54 is positioned between the gauge 50 andthe plate 24 along the hole 46 to form a seal between the gauge 50 andplate 24. A user can see the gauge 50 through the transparent topportion 22. By way of example only, the gauge 50 shows pressure inpounds per square inch. By way of example only, the body 14 and base 18may be made of steel, aluminum, or some other metal, the top portion 22may be made of polycarbonate, and the top plate 24 may be made of opaquealuminum or some other opaque material.

The pump 10 includes a handle assembly 58. The handle assembly 58includes a handle bar 62 having two grips 66 attached thereto. The grips66 can be slidably attached with adhesive to and removed from the handlebar 62 by maintenance staff. The handle bar 62 extends through, and isdetachably connected to, a cylindrical handle cap 70. The handle bar 62is detachably connected to the cap 70 by a tamper resistant fastener 74such as a bolt or screw. The handle assembly 58 is shown in the “down”position wherein the cap 70 is pushed down to the top portion 22 of thepump 10. By way of example only, the handle bar 62 and handle cap 70 areboth made of steel, aluminum, or some other metal, and the grips 66 aremade of a hard polymer or rubber material.

A flexible hose 26 is connected to a first adapter 28 that extends fromthe body 14 of the pump 10 through a gap 36. A head 30 with a nozzle 34is connected to the hose 26 by a second adaptor 38. By way of exampleonly, the hose 26 may be 36 or 48 inches long and made of rubber coveredwith stainless steel braiding. The adapters 28 and 38 may be made ofbrass or another kind of metal. The nozzle 34 is configured to be usedwith a bicycle tire valve to fill the tire with air; however, the nozzle34 can also be configured to fill other inflatable objects with air. Thehead 30 may be made of or include a magnetic material such that the head30 can be magnetically connected to the metal pump body 14.

FIG. 3 illustrates a sectional view of the pump 10 of FIG. 2 taken alonglines A-A. The handle assembly 58 is connected to a cylindrical pistonrod 78 that extends into the body 14 through holes 82 and 86 (FIG. 4) inthe top portion 22 and the top plate 24, respectively. The rod 78 isreceived in a cylindrical tube 90. The tube 90 is secured in the body 14by a top plate 92 and bottom plate 94 that extend from an interior wall98 of the body 14. The tube 90 includes a base plate 160 that isdetachably connected to the bottom plate 94 by a fastener 80. Thefastener 80 can be a screw and washer assembly. The tube 90 includes abushing 96 at the top end thereof that slidably receives the rod 78. Apiston 102 is connected to the bottom of the rod 78 by a screw 106. Thepiston 102 has two gaskets or O-rings 110 mounted thereto. The piston102 and the O-rings 110 form an air seal with the interior wall 114 ofthe tube 90. The outer diameter of the rod 78 is less than the innerdiameter 90 of the tube 90 so that there is an air gap between the rod78 and the tube 90 beneath the bushing 96 and above the piston 102. Byway of example only, the rod 78 and tube 90 are made of steel oraluminum or some other metal, the bushing 96 and piston 102 are made ofa hard polymer or plastic material, and the gaskets 110 are made of aflexible polymer or rubber material. If one of the gaskets 110 breaks orwears, it does not immediately need to be replaced because the secondgasket 110 maintains a seal with interior wall 114 of the tube.

A barbed fitting 118 extends from the bottom of the tube 90. A first airline 122 extends from the fitting 118 to a check valve 126 that extendsfrom the interior wall 98 of the body 14. A second air line 130 extendsfrom the check valve 126 to a three way barbed fitting 134 that extendsfrom the interior wall 98 of the body 14. A third air line 138 extendsfrom the three way barbed fitting 134 to a barbed fitting 142 connectedto the pressure gauge 50, which is mounted to the top plate 92. A fourthair line 146 extends from the three way barbed fitting 134 to a barbedfitting 150 that is connected to the first adapter 28. The air lines122, 130, 138, and 146 may be made of rubber, and the fittings 118, 134,142, and 150 may be made of steel or aluminum or some other metal.

FIG. 4 illustrates a partially exploded isometric view of the pump 10.The rod 78 (FIG. 3) is positioned in the tube 90, and the tube 90 isremoved from the body 14. The top plate 92 of the body 14 has four arms154 that have holes that are configured to receive rivet nuts 162. Therivet nuts 162 receive the bolts 16 that extend through the top portion22 and top plate 24 such that the top portion 22 and top plate 24 can besecured to the top plate 92 of the body 14. The top portion 22 and topplate 24 include holes 82 and 86 that receive the rod 78.

The top plate 92 also includes a hole 166 that receives the tube 90 whenthe tube 90 is placed in the body 14. The top plate 92 also supports thepressure gauge 50, which is connected to the barbed fitting 142 that isconnected to the third air line 138 (FIG. 3). The pressure gauge 50 maybe filled with oil so that the gauge 50 does not fog up in certain kindsof weather. In particular, the gauge 50 includes a chamber defined by aface and cover, and the chamber is filled at least partly with oil.

FIG. 5 illustrates an exploded view of piston 78, tube 90, and handleassembly 58. The tube 90 includes a base plate 160 that can be connectedto the bottom plate 94 (FIG. 3) of the body 14. The bushing 96 isconnected to the tube 90 by a screw and washer assembly 174. The barbedfitting 118 is configured to be connected to the bottom of the tube 90.

With respect to the piston rod 78, the piston 102 has grooves 178 on thecircumference thereof to receive the gaskets 110. Silicone grease may beapplied to the gaskets 110 once the gaskets 110 are attached to piston102. Another O-ring 182 is placed between the piston 102 and the rod 78when the piston 102 is connected to the rod 78 to form a seal betweenthe piston 102 and rod 78. The piston 102 is secured to the rod 78 bythe shoulder screw 106, which is secured by a set screw 186 that extendsthrough the body of the rod 78.

With respect to the handle assembly 58, the cap 70 includes horizontalholes 190 for receiving the handle bar 62 and a vertical hole 194 forreceiving the screw 74. The handle bar 62 also includes a vertical hole202, and the rod 78 includes a threaded bore 206 hole.

With reference to FIGS. 3, 4, and 5, the pump 10 is assembled asfollows. The cylindrical body 14 includes the top and bottom plates 92and 94, which are secured, such as by welding, to the interior wall 98thereof. The barbed fitting 118 is attached to the tube 90, and the tube90 is inserted into the body 14 from the bottom end such that a portionof the tube 90 is received in the hole 166 of the top plate 92 and thebase plate 160 of the tube 90 is secured to the bottom plate 94 of thebody 14 by the fastener 80. The gauge 50 is mounted on the top plate 92.The gauge 50 includes a lower portion 210 (FIG. 3) that extends througha hole in the top plate 92 into the interior of the body 14. By way ofexample only, the lower portion 210 of the gauge 50 can be threadablyconnected to the top plate 92, and Teflon tape can be applied to thethreads of the lower portion 210. Alternatively, the gauge 50 can bemounted to the top plate 92 in any number of other ways as well. Thebarbed fitting 142 is connected to the lower portion 210 of the gauge50.

The third air line 138 is connected to the barbed fitting 142 and thethree way barbed fitting 134, and the fourth air line 146 is connectedto the three way barbed fitting 134 and the barbed fitting 150. Thesecond air line 130 is connected to the check valve 126 and the threeway barbed fitting 134, and the first air line 122 is connected to thebarbed fitting 118 and the check valve 126. Sealant and/or hose clampsmay be used to attach the air lines to the barbed fittings. The hose 26is threadably connected to the head 30 by the adapter 38, and theadapter 28 of the hose 26 is threadably connected to the barbed fitting150 in the body 14. The adapter 38 can extend through the gap 36 intothe body 14 of the pump 10 so that a person cannot reach the adapter 38to unscrew it from the barbed fitting 150. Sealant may be used tothreadably connect the adapters 28 and 38 to the hose 26.

The piston rod 78 with the piston 102 attached thereto is inserted intothe tube 90 and then the bushing 96 is slid down along the piston rod 78until the bushing 96 is positioned inside of and on top of the tube 90.The bushing 96 is then secured to the tube 90 by the screw and washerassembly 174. The gasket 54 is positioned on the gauge 50, and the topportion 22 and top plate 24 are then secured to the top plate 92 by theconnectors 16.

The handle assembly 58 is assembled by inserting the handle bar 62through the horizontal holes 190 in the cap 70 such that the hole 202 inthe handle bar 62 is vertically aligned with the hole 194 in the cap 70.The screw 74 is inserted into the aligned holes 194 and 202 and then thecap is positioned on the rod 78 such the screw 74 can be threaded intothe bore hole 206 of the rod 78 to fasten the cap 70 to the rod 78. Thegrips 66 are then slid on to the handle bar 62 and held in place on thehandle bar 62 by glue or other adhesive.

Once the pump 10 is assembled, the pump 10 can be secured to a ground orfloor surface by anchors, such as bolts, that are inserted through theholes 42 of the base 18 into the ground. By way of example only, thepump 10 can be secured to the ground at a park, bike station, or storeor along a trail.

With respect to FIGS. 1-3, the bicycle pump 10 operates as follows. Abicyclist uses the pump 10 by placing the nozzle 34 of the pump 10 onthe valve of his or her bicycle tire. Air is released from the bicycletire valve into the hose 26 of the pump 10. The air travels from thehose 26 into the fourth airline 146 and to the three way barbed fitting134. The flow of the air then splits into two different paths. The airtravels through the second air line 130 to the check valve 126, whichprevents the air from flowing into the first air line 122. The air alsotravels through the third air line 138 to the pressure gauge 50, atwhich point the air can no longer travel any further. At this point, theflow of air from the bicycle tire to the pump 10 has reached a point ofequilibrium, and the air gauge 50 displays the pressure of the air atthat equilibrium point. While the gauge 50 shows the air pressure of asystem including the hose 26, the second, third, and fourth air lines,130, 138, and 146, and the bicycle tire, the amount of air in the hose26 and air lines 130, 138, and 146 is relatively small compared to theamount of air in the bicycle tire. Therefore, the gauge 50 provides areasonably good indication of the air pressure of the bicycle tire. Ifthe air pressure shown by the gauge 50 is lower than what is desirablefor bicycle tire, the bicyclist uses the pump 10 to fill the tire withmore air.

In particular, the bicyclist places at least one hand on the grips 66 ofthe handle assembly 58 and moves the piston rod 78 up and down in thedirection of Arrows A and B (FIG. 2). As the piston rod 78 is pulledupward in the direction of Arrow A, air is drawn into the tube 90beneath the piston 102 through an inlet (not shown) in the tube 90. Thebushing 96 is positioned to engage the top of the piston 102 to preventthe rod 78 from being pulled out of the tube 90. As the piston rod 78 ispushed downward in the direction of Arrow B toward the base plate 160 ofthe tube 90, the piston 102, which forms a seal with the interior of thetube 90, displaces air out of the tube 90 through the barbed fitting 118and into the first air line 122.

The displaced air then travels through the first air line 122 and thecheck valve 126 into the second air line 130. Once the air has passedthrough the check valve 126, the air cannot go back through the checkvalve 126 into the first air line 122. Therefore, the air pressure inthe second, third, and fourth air lines 130, 138, and 146 increases and,because the air cannot go back through the check valve 126 or throughthe gauge 50, the air travels through the fourth air line 146 into thehose 26 and into the bicycle tire. The air pressure in the bicycle tireincreases, as does the pressure in the second, third, and fourth airlines 130, 138, and 146, and this increase in air pressure is shown bythe gauge 50. The user continues to move the piston rod 78 up and downin this manner until the gauge 50 shows that the pressure in the system,and thus the tire, has reached a desirable level. The user thendisengages the nozzle 34 form the bicycle tire valve and magneticallyconnects the head 30 to the body 14 of the pump 10.

FIGS. 6 illustrates an isometric view of a pump 300 according to analternative embodiment of the present invention, and FIG. 7 illustratesa partially exploded isometric view of the pump 300 of FIG. 6. The pump300 operates in much the same way as pump 10 shown in FIGS. 1-5, butdoes not include an air pressure gauge and therefore is smaller and hasfewer parts. The pump 300 includes a cylindrical lower body 304 andcylindrical upper body 308. The upper body 308 is connected to acircular plate 312 that is detachably connected to the lower body 304 bytamper resistant fasteners 310. The lower body 304 includes a tab 316that has a hole 320 configured to receive an anchor or connector (notshown) that secures the tab 316 to the base plate of a bicycle repairstand, such as a Dero Fixit bicycle repair stand. The upper body 308includes a tab 342 that has a hole 346 configured to receive a bolt witha washer and tamper resistant nut that secures the tab 342 to the sideof a bike repair stand, such as a Dero Fixit bicycle repair stand. Thelower body 304 is open at the bottom. The pump 300 includes a handleassembly 324 that is similar to the handle assembly 58 shown in FIG. 1.The pump 300 also includes a hose 328 and head 332 that are similar tothose shown in FIG. 1. The hose 328 is connected to the head 332 by afirst adapter 336 and to the lower body 304 by a second adapter 344 thatextends from a gap 338 in the lower body 304. The hose 328 extendsthrough the tab 342. The head 332 may be magnetized such that the head332 can be magnetically secured to the metal upper body 308.

The pump 300 has a tube 340 that is similar to the tube 90 of FIGS. 3.The tube 340 is configured to be slidably received in the upper body308. The tube 340 slidably receives a piston rod assembly (not shown)similar to that of the pump 10 shown in FIG. 5. The tube 340 includes abushing similar to the bushing 96 shown in FIG. 5 that is detachablyconnected to the tube 340 by a tamperproof fastener 314. The fastener314 can be a screw and washer assembly. The fastener 314 is positionedin and accessible through a gap 318 in the upper body 308.

FIG. 8 illustrates a sectional side view of a portion of the pump 300.The tube 340 has a base plate 348 that is detachably secured to theplate 312 by the fastener 310. A first barbed fitting 352 extends fromthe base plate 348 of the tube 340. A first air line 354 extends fromthe barbed fitting 352 to a check valve 356, and a second airline 360extends from the check valve 356 to a second barbed fitting 364. Thesecond adapter 344 is connected to the second barbed fitting 364 andextends out of the gap 338 (FIG. 6) of the lower body 304 and isconnected to the hose 328. The hose 328 extends through the hose holdertab 342.

With reference to FIGS. 6-8, the pump 300 is assembled as follows. Thetube 340 is inserted into the lower and upper bodies 304 and 308 of thepump 300 through the open bottom of the lower body 304. The base plate348 of the tube 340 is secured to the plate 312 by the fastener 310. Thefirst air line 354 is connected to the first barbed fitting 352 and thecheck valve 356 with sealant. The second air line 360 is connected tothe check valve 356 and the second barbed fitting 364 with sealant. Thehead 332 is connected to the first adapter 336 of the hose 328, and thesecond adapter 344 of the hose 328 is connected to the second barbedfitting 364 and positioned in the gap 338 of the lower body 304. Theadapter 344 can extend through the gap 338 into the lower body 304 ofthe pump 300 so that a person cannot reach the adapter 344 to unscrew itfrom the barbed fitting 364. Sealant may be used to threadably connectthe adapters 336 and 344 to the hose 328, barbed fitting 364, and head332.

In operation, a bicyclist connects the head 332 of the pump 300 to thevalve of a bike tire. The bicyclist then uses at least one hand to gripthe handle assembly 324 and move the handle assembly 324 up and down inthe direction of Arrows A and B. As the bicyclist pulls the handleassembly 324 up in the direction of Arrow A, air is drawn into the tube340 below the piston (FIG. 3) through an inlet in the tube (not shown).As the bicyclist pushes the handle assembly 324 down in the direction ofArrow B, the piston pushes air down out of the tube 340 through thefirst barbed fitting 352 into the first air line 354. The air travelsfrom the first air line 354 through the check valve 356 into the secondair line 360. The air then moves from the second air line 360 throughthe second barbed fitting 364 and second adapter 344 into the hose 328.The air passes through the hose 328 and the head 332 into the bicycletire. The bicyclist continues operating the pump in this manner untilthe air pressure of the bicycle tire has reached a desirable level.

FIGS. 9 illustrates an isometric view of a pump 400 according to analternative embodiment of the present invention, and FIG. 10 illustratesa partially exploded isometric view of the pump 400 of FIG. 9. The pump400 operates in much the same way as pump 300 shown in FIGS. 6-8. Themain difference between pump 400 and pump 300 is that pump 400 includesa larger base plate 404 attached to the lower body 304 of the pump. Thebase plate 404 is circular and extends around the entire perimeter ofthe lower body 304. The base plate 404 includes multiple holes 408 thatare configured to receive fasteners or anchors (not shown) that securethe pump 400 to a ground surface. In this way, the pump 400 is securelyfastened to the ground surface while the pump 300 is fastened to abicycle repair stand.

The various pump embodiments 10, 300, and 400 may be configured to beused to inflate any number of other inflatable objects besides bicycletires and can be used in any number of different locations. The pumpembodiments of the present invention are made of robust and durablematerials and components that provide for greater component lifespanseven though the pumps are located outside and are exposed to theelements and repeated use by numerous different bicyclists. For example,many of the components are made of steel or aluminum and the hoseincludes metal braiding and is threadably connected to metal adapters toprevent the hose from easily being detached or damaged. Moreover, thepumps are easy to disassemble, and many of the components are removable.Therefore, if an individual component does wear out or break, thecomponent can easily be removed and replaced without the need to replacethe entire pump. For example, the hose, air lines, handle, and air gaugecan all easily be removed and replaced by maintenance staff with specialtools for tamper resistant hardware. The pumps may also include userfriendly features such as an oil-filled pressure gauge that does not fogup and a pump head that can be magnetically connected to the pump body.

While various spatial and directional terms, such as top, bottom, lower,mid, lateral, horizontal, vertical, front and the like may used todescribe embodiments of the present invention, it is understood thatsuch terms are merely used with respect to the orientations shown in thedrawings. The orientations may be inverted, rotated, or otherwisechanged, such that an upper portion is a lower portion, and vice versa,horizontal becomes vertical, and the like.

Variations and modifications of the foregoing are within the scope ofthe present invention. It is understood that the invention disclosed anddefined herein extends to all alternative combinations of two or more ofthe individual features mentioned or evident from the text and/ordrawings. All of these different combinations constitute variousalternative aspects of the present invention. The embodiments describedherein explain the best modes known for practicing the invention andwill enable others skilled in the art to utilize the invention. Theclaims are to be construed to include alternative embodiments to theextent permitted by the prior art.

Various features of the invention are set forth in the following claims.

1. A pump for inflating tires with air, comprising: a body having a topportion, wherein the body is configured to be anchored to anotherstructure and the top portion is detachably connected to an upper platethat extends from an inner wall of the body; a handle assembly includinga piston rod and a handle bar; a tube positioned in said body, said tubereceiving said piston rod such that a piston mounted on the piston rodslides in the tube and said tube being connected to an air line; and ahose connected to said air line and extending from said body, said hosehaving a head configured to engage a nozzle of a tire; wherein, whensaid piston rod is moved downward within said tube, air is displacedfrom said tube and through said air line to said hose such that saidhead dispenses air.
 2. The pump of claim 1, wherein the air linecomprises (a) a first air line portion that is connected at a first endto the fitting extending from the tube and that is connected at a secondend to a check valve and (b) a second air line portion that is connectedat another first end to the check valve and that is connected at anothersecond end to the adaptor connected to the hose.
 3. The pump of claim 1,wherein the hose is threadably connected to the adapter that isconnected to the air line.
 4. The pump of claim 3, wherein a portion ofthe hose is made of threaded metal.
 5. The pump of claim 1, wherein thepiston rod includes two flexible gaskets that each form a seal with aninterior wall of the tube.
 6. The pump of claim 1, wherein the body,handle bar, piston rod, and tube are each made of either steel oraluminum.
 7. The pump of claim 1, wherein the handle assembly includesrubber grips that are slidably mounted to the handle bar.
 8. The pump ofclaim 1, wherein the body is open at a bottom end thereof to provideaccess to the tube inside the body.
 9. The pump of claim 1, wherein thehead magnetically connects to the body.
 10. The pump of claim 1, whereinthe tube rests on the lower plate.
 11. A pump for inflating tires withair, comprising: a body having top portion, wherein the body isconfigured to be anchored to another structure and the top portion isdetachably connected to the body by a fastener; a handle assemblyincluding a piston rod and a handle bar; a tube positioned in the bodyand supported by a plate that extends from an inner wall of the body,the tube receiving the piston rod such that a piston mounted on thepiston rod slides in the tube and the tube being connected to an airline via a fitting extending from below the plate into a gap between theplate and a bottom of the body, wherein the air line includes a flexibletube and extends from the fitting to an adapter located proximate thetop portion; and a hose connected to the air line via the adapter andextending from the body, the hose having a head configured to engage anozzle of a tire; wherein, when the piston rod is moved downward withinthe tube, air is displaced from the tube and through the air line to thehose such that the head dispenses air.
 12. The pump of claim 11, whereinthe air line comprises (a) a first air line portion that is connected ata first end to the fitting extending from the tube and that is connectedat a second end to a check valve and (b) a second air line portion thatis connected at another first end to the check valve and that isconnected at another second end to the adaptor connected to the hose.13. The pump of claim 11, wherein the hose is threadably connected tothe adapter that is connected to the air line.
 14. The pump of claim 13,wherein a portion of the hose is made of threaded metal.
 15. The pump ofclaim 11, wherein the piston includes two flexible gaskets that eachform a seal with an interior wall of the tube.
 16. The pump of claim 11,wherein the body, handle bar, piston rod, and tube are each made ofeither steel or aluminum.
 17. The pump of claim 11, wherein the handleassembly includes rubber grips that are slidably mounted to the handlebar.
 18. The pump of claim 11, wherein the body is open at the bottom toprovide access to the tube inside the body.
 19. The pump of claim 11,wherein the head magnetically connects to the body.
 20. The pump ofclaim 11, wherein the tube rests on the plate.